Chapter 7

Chapter 7 Let the Titrations Begin

Titration • Titration • A procedure in which one substance (titrant) is carefully added to another (analyte) until complete reaction has occurred. • The quantity of titrant required for complete reaction tells how much analyte is present. • Volumetric Analysis • A technique in which the volume of material needed to react with the analyte is measured

Titration Vocabulary • Titrant • The substance added to the analyte in a titration (reagent solution) • Analyte • The substance being analyzed • Equivalence point • The point in a titration at which the quantity of titrant is exactly sufficient for stoichiometric reaction with the analyte.

Titration Vocabulary • End point • The point in a titration at which there is a sudden change in a physical property, such as indicator color, pH, conductivity, or absorbance. Used as a measure of the equivalence point. • Indicator • A compound having a physical property (usually color) that changes abruptly near the equivalence point of a chemical reaction.

Titration Vocabulary • Titration error • The difference between the observed end point and the true equivalence point in a titration • Blank Titration • One in which a solution containing all reagents except analyte is titrated. The volume of titrant needed in the blank titration should be subtracted from the volume needed to titrate unknown.

Titration Vocabulary • Primary Standard • A reagent that is pure enough and stable enough to be used directly after weighing. Then entire mass is considered to be pure reagent. • Standardization • The process whereby the concentration of a reagent is determined by reaction with a known quantity of a second reagent.

Titration Vocabulary • Standard Solution • A solution whose composition is known by virtue of the way it was made from a reagent of known purity or by virtue of its reaction with a known quantity of a standard reagent. • Direct Titration • One in which the analyte is treated with titrant, and the volume of titrant required for complete reaction is measured.

Titration Vocabulary • Back Titration • One in which an excess of standard reagent is added to react with analyte. Then the excess reagent is titrated with a second reagent or with a standard solution of analyte.

Titration Calculations • Titration Calculations rely heavily on the ability to perform stoichiometric calculations. • Examples

Titration Calculation Examples • How many milligrams of oxalic acid dihydrate, H2C2O4. 2H2O (FM = 126.07), will react with 1.00 mL of 0.0273 M ceric sulfate (Ce(SO4)2) if the reaction is: H2C2O4 + 2Ce4+ 2CO2 + 2Ce3+ + 2H+

Titration Calculation Examples • A mixture weighing 27.73 mg containing only FeCl2 (FM = 126.75) and KCl (FM = 74.55) required 18.49 mL of 0.02237 M AgNO3 for complete titration of the chloride. Find the mass of FeCl2 and the weight percent of Fe in the mixture.

Titration Calculation Examples • The calcium content of urine can be determined by the following procedure • Step 1. Ca2+ is precipitated as calcium oxalate in basic solution: Ca2+ + C2O42- + H2O  Ca(C2O4) . H2O(s) • Step 2. After the precipitate is washed with ice-cold water to remove free oxalate, the solid is dissolved in acid, which gives Ca2+ and H2C2O4 in solution. • Step 3. The dissolved oxalic acid is heated at 60oC and titrated with standardized potassium permanganate until the purple end point of the following reaction is observed: 5H2C2O4 + 2MnO4- + 6H+  10CO2 + 2Mn2+ + 8H2O

Titration Calculation Examples • Standardization: Suppose that 0.3562 g of Na2C2O4 is dissolved in a 250.0 mL volumetric flask. If 10.00 mL of this solution require 48.36 mL of KMnO4 solution for titration, what is the molarity of the permanganate solution? • Calcium in a 5.00-mL urine sample was precipitated, was redissolved, and then required 16.17 mL of standard MnO4- solution. Find the concentration of Ca2+ in the urine

Titration Calculation Examples • A solid mixture weighing 1.372 g containing only sodium carbonate and sodium bicarbonate required 29.11 mL of 0.734 M HCl for complete titration: Na2CO3 + HCl  2NaCl(aq) + H2O + CO2 NaHCO3 + HCl  NaCl(aq) + H2O + CO2 Find the mass of each component of the mixture.

Titration Calculations • Kjeldahl Nitrogen Analysis • Digest the organic compound in boiling H2SO4 to convert Nitrogen to NH4+ • Hg, Cu, or Se will catalyze the digestion process • Raise the b.p. of H2SO4 (338oC) by adding K2SO4 to increase the rate of the reaction

Titration Calculations • Kjeldahl Nitrogen Analysis • Treat the ammonium compound with base and distill as ammonia into a standard acidic solution • NH4+ + OH- NH3(g) + H2O • NH3 + H+  NH4+ • The moles of acid consumed equal the moles of NH3 liberated • H+ (HCl) + OH-(NaOH)  H2O

Titration Calculation Examples • A typical protein contains 16.2 wt% nitrogen. A 0.500-mL aliquot of protein solution was digested, and the liberated ammonia was distilled in 10.00 mL of 0.02140 M HCl. The unreacted HCl required 3.26 mL of 0.0198 M NaOH for complete titration. Find the concentration of protein (mg protein / mL) in the original sample.

Spectrophotometric Titrations • One in which absorption of light is used to monitor the progress of the chemical reaction

Spectrophotometric Titration Example • 2Fe3+ + Apotransferrin  (Fe3+)2transferrin • Apotransferrin is clear • (Fe3+)2transferrin is red • Absorption increases as a result of red from Iron attachment to the apotransferrin • Saturated protein – no further color change – absorption levels off • Extrapolated intersection is the equivalence point

Spectrophotometric Titration Example • Construction of Graph • When constructing the graph of the absorbance values versus the concentration of Fe3+ you must take in account the dilution factor • Corrected absorbance = (total Volume / initial Volume)(observed absorbance)

Corrected Absorbance Calculations • The absorbance measured after adding 125 L of ferric nitrilotriacetate to 2.000 mL of apotransferrin was 0.260. Calculate the corrected absorbance that should be plotted.

Titration Curve • Titration Curve is a result of plotting p[X] (p[X]=-log [X]) versus the concentration of the titrant • Precipitation Titration • Concentration of analyte, concentration of titrant and the Ksp influence the sharpness of the endpoint • Acid-Base reaction and Oxidation-Reduction reactions • Have to calculate the theoretical endpoint to determine the indicator to be used

Precipitation Titration Curve • Example – AgI(s) formation • Ag+ + I- AgI(s) • Reverse of the Ksp reaction for the dissociation of AgI(s) so the K for this reaction equal 1/Ksp[AgI(s)] = 1.2 X 1016 • Large K value means that the equilibrium lies to the right for this reaction • Each aliquot addition of Ag+ titrant reacts virtually entirely to form AgI(s)

Precipitation Titration Curve • Titration Curves typically exhibit 3 distinct regions for a single titrant reacting with a single analyte. • Before the Equivalence Point • At the Equivalence Point • After the Equivalence Point

Precipitation Titration Curve • Before the Equivalence Point • Example of AgI(s) formation • Most of the [Ag+] reacts entirely to give AgI • p[Ag+] = • the amount of Ag+ left in solution • The amount of I- present • From Ksp determine the amount of Ag+ present

Precipitation Titration Curve • At the equivalence point • Stoichiometric amount of Ag+ as I- so all has precipitated out as AgI(s) • Regular Ksp calculations

Precipitation Titration Curve • After Equivalence Point • [Ag+] is determined by the Ag+ present after the equivalence point with the dilution factor taken into account

Precipitation Titration Curve Equations • Calculate the Volume of Titrant needed to reach equilibrium MTVT = (Mole ratio)MAVA • Before the Equivalence Point [A] = (Fraction of Titrant Remaining)(M of Analyte)(Original Volume of solution / Total Volume of solution) [T] = Ksp / [A] pT = -log[T]

Precipitation Titration Curve Equations • At Equivalence Point [A][T] = Ksp Calculate like in section 6-3 • After the Equivalence Point [T] = (Original Concentration of Titrant)(Volume of excess Titrant / Total Volume of Solution) pT = -log[T]

Precipitation Titration Curve Example • 25.00 mL of 0.1000 M I- was titrated with 0.05000M Ag+. Ag+ + I- AgI(s) The solubility product for AgI is 8.3 x 10-17. Calculate the concentration of Ag+ ion in solution (a) after addition of 10.00 mL of Ag+; (b) after addition of 52.00 mL of Ag+; (c) at the equivalence point.

Precipitation Titration Curve Example • 25.00 mL of 0.04132 M Hg2(NO3)2 was titrated with 0.05789 M KIO3. Hg22+ + 2IO3- Hg2(IO3)2(s) The solubility product for Hg2(IO3)2 is 1.3 x 10-18. Calculate the concentration of Hg22+ ion in solution (a) after addition of 34.00 mL of KIO3; (b) after addition of 36.00 mL of KIO3; (c) at the equivalence point.

Precipitation Titration Curve Example • Consider the titration of 50.00 mL of 0.0246 M Hg(NO3)2 with 0.104 KSCN. Calculate the value of pHg22+ at each of the following points and sketch the titration curve: 0.25VT 0.5VT 0.75VT 1.05VT 1.25VT

Titration Curve Shape • 1:1 Stoichiometry of Reagents • Equivalence point is the steepest point of a curve • Maximum slope • An inflection point • Other Stoichiometries • The curve is not symmetric about the equivalence point • The equivalence point is not at the center of the steepest section of the curve • The less soluble the product, the sharper the curve around the equivalence point

Titration Curve Shape

Titration of a Mixture • The less soluble product forms first • If there is sufficient difference in solubility of products • First precipitation is nearly complete before the second one begins • Separation by precipitation (section 6-5) • Coprecipitation • Alters the expected endpoints

Titration of a Mixture Example

Chapter 7 - Homework • Problems – 2, 4, 8, 11, 12, 18, 22, 23, 28

Chapter 7

Chapter 7

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Chapter 7

Chapter 7

Chapter 7

CHAPTER 7

Chapter 7

Chapter 7

Chapter 7

Chapter 7

Chapter 7

Chapter 7

Chapter 7

Chapter 7

Chapter 7

Chapter 7

Chapter 7

Chapter 7

Chapter 7

Chapter 7

Chapter 7

Chapter 7

Chapter 7

Chapter 7